Deposition and assembly of magnesium hydroxide nanostructures on zeolite 4A surfaces

Koh, Pei Yoong

15 November 2010

A deposition - precipitation method was developed to produce magnesium hydroxide / zeolite 4A (Mg(OH)₂ - Z4A) nanocomposites at mild conditions and the effect of processing variables such as precursor concentration, type of base added, and synthesis time on the composition, size, and morphology of the nanocomposite were studied. It was determined that the precursor concentration, basicity, and synthesis time had a significant effect on the composition, size, and morphology of the deposited magnesium hydroxide (Mg(OH)₂) nanostructures. The properties of the Mg(OH)₂ - Z4A such as surface area, pore volume and composition were characterized. Mg(OH)₂ - Z4A samples and bare zeolite 4A were dispersed in Ultem® polymer to form a mixed matrix membrane. The thermal and mechanical properties of the resulting films were investigated. It was found that the addition of rigid bare zeolites into the polymer decreased the mechanical properties of the polymer composite. However, some of these adverse effects were mitigated in the polymer composite loaded with Mg(OH)₂ - Z4A samples. Isotherms for the adsorption of Mg(OH)₂ petals on zeolite 4A were measured in order to determine the optimum conditions for the formation of magnesium hydroxide / zeolite 4A nanocomposites at ambient conditions. The loading of the Mg(OH)₂ can be determined from the adsorption isotherms and it was also found that the adsorption of Mg(OH)₂ on zeolite A occurs via 3 mechanisms: ion exchange, surface adsorption of Mg²⁺ ions, and surface precipitation of Mg(OH)₂. Without the addition of ammonium hydroxide, the predominant processes are ion exchange and surface adsorption of Mg²⁺ ions. In the presence of ammonium hydroxide, Mg(OH)₂ crystals are precipitated on the surface of zeolite 4A at moderate Mg²⁺ ions concentration and the loading of Mg(OH)₂ was found to increase with increasing Mg²⁺ ions concentration. A detailed examination of the interactions between Mg(OH)₂ and functional groups on the zeolite surface was conducted. Solid-state 29Si, 27Al, and 1H NMR spectra were coupled with FTIR measurements, pH and adsorption studies, and thermogravimetric analyses to determine the interactions of Mg(OH)₂ with surface functional groups and to characterize structural changes in the resulting zeolite after Mg(OH)₂ deposition. It was discovered that acid - base interactions between the weakly basic Mg(OH)₂ and the acidic bridging hydroxyl protons on zeolite surface represent the dominant mechanism for the growth of Mg(OH)₂ nanostructures on the zeolite surface.

Adsorption isotherms

Solid-state NMR

Nanocomposite

Deposition-precipitation

Zeolite

Magnesium hydroxide

Zeolites

Nanocomposites (Materials)

Nanostructures

Metallic oxides

The rheology and phase separation kinetics of mixed-matrix membrane dopes

Olanrewaju, Kayode Olaseni

18 January 2011

Mixed-matrix hollow fiber membranes are being developed to offer more efficient gas separations applications than what the current technologies allow. Mixed-matrix membranes (MMMs) are membranes in which molecular sieves incorporated in a polymer matrix do separation between gas mixtures based on the molecular size difference and/or adsorption properties of the component gases vis-à-vis the porous structure and the nature of adsorption sites in the molecular sieve. The development of MMMs to deliver on its promises has however been slow. The major challenges encountered in the efficient development of MMMs are associated with some of the paradigm shifts involved in their processing. For instance, mixed-matrix hollow fiber membranes are prepared by a dry-wet jet spinning method. For an efficient large scale processing of hollow fibers the rheology and kinetics of phase separation of the MMM dopes are important control variables in the process design. Therefore, this research thesis aims to study the rheology and phase separation kinetics of mixed-matrix membrane dopes. In research efforts to develop predictive models for the shear rheology of suspensions of zeolite particles in polymer solutions it was found that MFI zeolite suspensions have relative viscosities that dramatically exceed the Krieger-Dougherty predictions for hard sphere suspensions. Our investigations show that the major origin of this discrepancy is the selective absorption of solvent molecules from the suspending polymer solution into the zeolite pores. Consequently, both the viscosity of the polymer solution and the particle contribution to the suspension viscosity are greatly increased. A predictive model for the viscosity of porous zeolite suspensions incorporating a solvent absorption parameter, α, into the Krieger-Dougherty model was developed. We experimentally determined the solvent absorption parameter and our results are in good agreement with the theoretical pore volume of MFI particles. In addition, fundamental studies were conducted with spherical nonporous silica suspensions to elucidate the role of colloidal and hydrodynamic forces on the rheology of mixed-matrix membrane dopes. Also in this thesis, details of a novel microfluidic device that enables measurements of the phase separation kinetics via video-microscopy are presented. Our device provides a well-defined sample geometry and controlled atmosphere for in situ tracking of the phase separation process. We have used this technique to quantify the phase separation kinetics (PSK) of polymer solutions and MMM dopes upon contact with an array of relevant nonsolvent. For the polymer solution, we found that PSK is governed by the micro-rheological and thermodynamic properties of the polymer solution and nonsolvent. For the MMM dopes, we found that the PSK is increased by increased particles surface area as a result of surface diffusion enhancement. In addition, it was found that the dispersed particles alter the thermodynamic quality of the dope based on the hydrophilic and porous nature of suspended particles.

Polymer solution

Rheology

Phase separtion kinetics

Membranes

Suspensions

Zeolite particles

Membranes (Technology)

Separation (Technology)

Zeolites

Rheology

Liquation

Reverse-selective zeolite/polymer nanocomposite hollow fiber membranes for pervaporative biofuel/water separation

McFadden, Kathrine D.

08 April 2010

Pervaporation with a "reverse-selective" (hydrophobic) membrane is a promising technology for the energy-efficient separation of alcohols from dilute alcohol-water streams, such as those formed in the production of biofuels. Pervaporation depends on the selectivity and throughput of the membrane, which in turn is highly dependent on the membrane material. A nanocomposite approach to membrane design is desirable in order to combine the advantages and eliminate the individual limitations of previously-reported polymeric and zeolitic membranes. In this work, a hollow-fiber membrane composed of a thin layer of polymer/zeolite nanocomposite material on a porous polymeric hollow fiber support is developed. The hollow fiber geometry offers considerable advantages in membrane surface area per unit volume, allowing for easier scaling and higher throughput than flat-film membranes. Poly(dimethyl siloxane) (PDMS) and pure-silica MFI zeolite (silicalite-1) were investigated for these membranes. Iso-octane was used to dilute the dope solution to provide thinner coatings. Previously-spun non-selective Torlon hollow fibers were used as the support layer for the nanocomposite coatings. To determine an acceptable method for coating fibers with uniform, defect-free coatings, flat-film membranes (0 to 60 wt% MFI on a solvent-free basis) and hollow-fiber membranes (0 and 20 wt% MFI) were fabricated using different procedures. Pervaporation experiments were run for all membranes at 65C with a 5 wt% ethanol feed. The effects of membrane thickness, fiber pretreatment, coating method, zeolite loading, and zeolite surface treatment on membrane pervaporation performance were investigated.

Ethanol/water pervaporation

Hydrophobic pervaporation

Mixed-matrix membrane

Composite membrane

Pervaporation

Biomass energy

Gas separation membranes

Zeolites

Nanocomposites

Revalorización catalítica de glicerina para una obtención más respetuosa con el medio ambiente de aditivos para combustibles

González Candela, Mª Dolores

14 October 2011

Durante la fabricación del biodiesel se obtiene glicerina (o glicerol) como subproducto (10 % en peso del producto total) dando lugar a importantes excedentes. Por tanto, es necesario buscar nuevas vías de transformación de glicerina en productos de alto valor añadido. Una de las reacciones a estudiar es la eterificación de glicerol, en presencia de tert-butanol o isobuteno, para la obtención de los di- y tri-tert-butil éteres de glicerol (h-GTBE), que se pueden utilizar como aditivos oxigenados en combustibles. Por ello, en esta tesis se han preparado, modificado y caracterizado tres zeolitas, una zeolita con porosidad jerarquizada, un aerogel y un liogel de sílice, además de materiales mesoporosos ordenados para su uso como nuevos catalizadores heterogéneos ácidos activos y selectivos hacia la formación de di- y tri-tert-butil éteres de glicerol (h-GTBEs) en la reacción de eterificación de glicerol con tert-butanol o isobuteno. Otro de los objetivos importantes de esta tesis ha sido el estudio del efecto de la radiación microondas (autoclave y reflujo) en la desaluminación de tres zeolitas comerciales. La radiación microondas se ha empleado también en la sulfonación de zeolitas, materiales mesoporosos ordenados, montmorillonita K-10, aerogel y liogel sílice. La incorporación de grupos sulfónicos en estos materiales nos ha permitido obtener elevadas conversiones (100 %) y selectividades hacia los productos de interés (91 %). / There is an increasing interest in searching new processes to transform glycerol (surplus in the biodiesel manufacture) into high-added value products. In addition, the use of microwaves for the synthesis and modification of materials is becoming an important tool to reduce the synthesis time (energy saving). In this thesis, we prepared, modified and characterized three zeolites, a zeolite with hierarchical porosity, an aerogel and a liogel of silica and ordered mesoporous materials to be tested as new heterogeneous catalysts for the glycerol etherification with tert-butanol or isobutene to obtain selectively di- and tri-ethers of glycerol (h-GTBE), which can be used as fuel additives. Other important objective of this thesis was to study the effect of using microwaves during dealumination of three zeolites on their resulting surface and acidic properties and during sulfonation of zeolites, montmorillonite K-10, aerogel, and liogel of silica and ordered mesoporous materials. The incorporation of sulfonic groups into these materials resulted in higher conversion (100 %) and higher selectivity (91 %) to desired products than non-functionalized materials.

Glicerina

Eterificació de glicerol

Catàlisi heterogènia

Microones

Zeolites

Aerogel

Liogel

Materials mesoporos ordenats

Èters de glicerol

glicerol

54

546

Toward green processes organic synthesis by catalysis with metal-doped solids

Borghese, Sophie

15 February 2013

Nowadays, the modern chemical industry has to deal with increasing environmental concerns, including the disposal of waste and its economic impact, or the diminution of important worldwide resources such as transition metals. In this Ph.D. thesis, we aimed to bring improvement in this area by the development of green processes, based on the use of recyclable heterogeneous catalysts. By combining the catalytic properties of several metal cations with the properties of solid catalysts such as polyoxometalates or zeolites, we were able to set up new tools for organic synthesis. Silver-doped polyoxometalates proved to be very efficient catalysts in the rearrangement of alkynyloxiranes to furans. Acetals and spiroketals were synthetized by dihydroalkoxylation of alkynediols under catalysis with silver-zeolites. As a perspective, we highlighted the potential applications of such green procedures in the total synthesis of more complex molecules. The first results suggested that these environmental friendly processes should gain increasing interest in the future.

[CHIM:OTHE] Chemical Sciences/Other

[CHIM:OTHE] Chimie/Autre

Green chemistry

Heterogeneous catalysis

Polyoxometalates

Furans

Zeolites

Spiroketals

Alkanes

Hydride transfer

Zeolites as key-components for electronics and biomedicine

Lülf, Henning

13 December 2013

The aim of this thesis titled "Zeolites as key-components for electronics and biomedicine" is the synthesis, functionalization and applications of zeolite-L particles for applications in electronics and biomedicine. This thesis is organized into 8 chapters, starting in chapter 1 with giving a general overview about nanotechnology and biomedicine. After that the concept of using nanocontainer in biomedicine are briefly discussed. In the following the nanocontainer zeolite-L is introduced and a summary of zeolite- L for applications in nanomedicine is given. Finally, the self-assembly of zeolites in monolayers and their further functionalization is discussed. Chapter 2 describes the zeolite-L synthesis, functionalization and their assembly into functional materials in detail. Three different types of zeolite-L have been used in this thesis: Nanozeolite-L particles with a size of just a few tenths of nanometers, disc-shaped zeolite-L with a diameter of around 200 nm and micrometer sized crystals with a length of about 1000 nm. Then different methods to functionalize the crystals with the desired groups and to obtain specific properties of the crystals are reported. In detail, the exchange with different counter cations, the insertion of guest molecules and the functionalization of the external crystal surface are reported. Finally the assembly into monolayers and their further functionalization by soft lithography is discussed. [...]

[CHIM:OTHE] Chemical Sciences/Other

[CHIM:OTHE] Chimie/Autre

Zeolites

Nanotechnology

Biomedicine

Magnetoresistance

Drug delivery

Gene therapy

Self assembly

Oligonucleotides

Morphological Control of Multifunctional Mesoporous Silica Nanomaterials for Catalysis Applications

Seong Huh

January 2004

Thesis (Ph.D.); Submitted to Iowa State Univ., Ames, IA (US); 19 Dec 2004. / Published through the Information Bridge: DOE Scientific and Technical Information. "IS-T 2397" Seong Huh. US Department of Energy 12/19/2004. Report is also available in paper and microfiche from NTIS.

Θεωρητική και πειραματική μελέτη της απόκρισης ζεολίθων σε μεταβολές θερμοκρασίας, πίεσης και συγκέντρωσης ροφημένων ουσιών

Κροκιδάς, Παναγιώτης

10 May 2012

Οι ζεόλιθοι ανήκουν στα νανοπορώδη υλικά ή αλλιώς και μοριακά κόσκινα. Βρίσκουν δε εφαρμογή σε πληθώρα εφαρμογών, καλύπτοντας ένα μεγάλο θερμοκρασιακό φάσμα. Η γνώση της απόκρισής τους κατά τις μεταβολές της θερμοκρασίας είναι καθοριστικής σημασίας για την αποδοτικότητά τους, ακόμα περισσότερο όταν εμφανίζονται ανώμαλα φαινόμενα, όπως αρνητικός συντελεστής θερμικής διαστολής. Η παρούσα εργασία επικεντρώνεται στην ερμηνεία αυτού του φαινομένου με την χρήση προσομοιώσεων και πειραμάτων σκέδασης ακτίνων Χ. Ένα νέο πεδίο δυνάμεων αναπτύχθηκε και χρησιμοποιήθηκε σε προσομοιώσεις δυναμικής πλέγματος, όπου για πρώτη φορά προβλέπεται η συστολή της μοναδιαίας κυψελίδας του σιλικαλίτη, όπως και η διαστολή της μοναδιαίας κυψελίδας του αργιλοπυριτικού φωγιασίτη (NaX) πάνω από την θερμοκρασία δωματίου. Περαιτέρω ανάλυση των αποτελεσμάτων δείχνει πως υπεύθυνες για την συστολή κατά την θέρμανση είναι οι περιστροφές των τετραέδρων SiO4 και AlO4 από τα οποία απαρτίζεται η δομή. Αυτό το αποτέλεσμα είναι σύμφωνο με τον μηχανισμό των περιστροφών άκαμπτων μονάδων που προτείνεται στην βιβλιογραφία (R.U.M.). Στη συνέχεια υπολογίζονται μηχανικές ιδιότητες του υλικού, όπως το μέτρο Young και το μέτρο ελαστικότητας όγκου. Τέλος μελετήθηκε η απόκριση της δομής των ζεολίθων σε ερεθίσματα πέραν της θερμοκρασίας, όπως μεταβολή πίεσης και ρόφηση μορίων. Χαρακτηριστικά καταλήγουμε πως η δομή αποκρίνεται στην άσκηση της πίεσης μέσω του ίδιου μηχανισμού που καθορίζει της θερμοκρασιακή της απόκριση, δηλαδή τις περιστροφές των άκαμπτων ή σχεδόν άκαμπτων τετραέδρων. Επίσης, σε ό, τι αφορά την επίδραση της ρόφησης, η παρουσία των μορίων εξανίου, παρόλο επιφέρει δομικές αλλαγές που βελτιώνουν την αποδοτικότητα των ζεολιθικών μεμβρανών, αυτές οι αλλαγές δεν επηρεάζουν τις ροφητικές ιδιότητες στο εσωτερικό του κρυστάλλου. / Zeolites are nanoporous materials, otherwise called molecular sieves. The knowledge of the response of a zeolite structure to temperature changes or to the presence of host molecules in the pore system is of critical significance for the performance of zeolites as molecular sieves, especially if they are prepared in the form of membranes. Crack formation or grain boundary openings may appear between the substrate and the membrane due to a mismatch between the thermal expansion coefficient of the two materials, affecting the sorption and selectivity properties of the membrane. The problem is enhanced when the zeolite shows negative thermal expansion coefficient. The present work focuses in the mechanism that lies behind contraction upon heating, with the use of simulations and powder XRD experiments. A new force field was developed and was implemented in lattice dynamics simulations. It’s the first time that simulations predict the contraction of silicalite unit cell as well as the expansion of aluminosilicate faujasite (NaX) unit cell above room temperature. Further analysis of the simulation data shows that the Rigid Unit Mode (R.U.M.) mechanism that is proposed in the literature is the dominant mechanism of thermal contraction of the zeolite. Furthermore, mechanical properties such as Young modulus and bulk modulus were computed with the use of the newly derived force field. Finally, the response of framework upon pressure change and sorption of molecules was investigated. The zeolite structure response upon pressure change is similar to this of the temperature response, meaning that the volume and atomic positions change with the help of the rotations of the rigid AlO2/SiO2 tetrahedra. Concerning the response upon sorption, is was found with the help of theoretical calculations that although unit cell size variations that are induced by temperature changes and/or sorption may affect the efficiency of silicalite-1 membrane performance through alteration of the size of the non-zeolitic pores, such changes appear to affect negligibly the bulk sorption capacity of the silicalite-1 crystals.

Ζεόλιθοι

Προσομοίωση

Πεδία δυνάμεων

Φωγιασίτης

549.68

Zeolites

Simulation

Negative thermal expansion

Forcefields

Faujasite

Extreme water catalyzed transformations of SiO2, TiO2 and LiAlSiO4

Spektor, Kristina

January 2015

The dramatic change in properties of water near its critical point (i.e. T = 374 °C and p = 22.1 MPa, note: 100 MPa = 0.1 GPa = 1 kbar ≈ 1000 atm) has been a subject of numerous studies and also lead to the development of various applications (e.g. in waste destruction, biomass processing, and the synthesis of advanced ceramic materials). However, comparatively little is known about the behavior of water at gigapascal pressures. The present study attempts to explore catalytical properties and reactivity of extreme water with respect to several oxide systems: SiO2, TiO2 and LiAlSiO4. “Extreme water” here is defined as existing at p,T conditions of 0.25–10 GPa and 200–1000 °C, thus considering both supercritical fluid and hot compressed ice. The study shows that extreme water can make high pressure mineral phases accessible at relatively mild T conditions. At the same time, high pressure aqueous environments appear efficient in stabilizing novel metastable structures and may be considered as a general route for synthesizing new materials. The hydrothermal treatment of SiO2 glass at 10 GPa and 300–550 °C yielded an unusual ultrahydrous form of stishovite with up to 3% of structural water. At the same time, the extreme water environment enhanced notably the kinetics of stishovite formation, making it accessible at unprecedentedly low temperatures. Thus, for the SiO2–H2O system water acts as both catalyst and reactant. For TiO2 a hydrothermal high pressure treatment proved to be of high importance for overcoming the kinetical hindrance of the rutile – TiO2-II transformation. 6 GPa and 650 °C were established as the mildest conditions for synthesizing pure TiO2-II phase in less than two hours. The crystallization of LiAlSiO4 glass in an extreme water environment yielded a number of different phases. In the low pressure region (0.25 – 2 GPa) mainly a zeolite (Li-ABW) and a dense anhydrous aluminosilicate (α-eucryptite) were obtained. At pressures above 5 GPa the formation of novel pyroxene-like structures with crystallographic amounts of structural water was observed. The overall conclusion of this study is that extreme water environments show a great potential for catalyzing phase transitions in oxide systems and for stabilizing novel structures via structural water incorporation. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 4: Manuscript.</p>

extreme water environments

high pressure polymorphism

hydrous stishovite

titania phase transitions

lithium aluminosilicates

zeolites from glass precursors

hydrous pyroxenes

Microcapteurs chimiques à base de micropoutres en silicium modi?ées à l’aide de matériaux inorganiques microporeux

Tétin, Sébastien

14 December 2009

Afin d'optimiser l'utilisation des micropoutres en tant que capteurs chimiques, de nouvelles couches sensibles à base de matériaux microporeux ont été testées pour la détection d'humidité, de toluène et d'éthanol. Des essais sans couches sensibles ont aussi été effectués et des modèles simples ont été mis au point afin de prédire la réponse des micropoutres lors d'un changement d'environnement. Ces études ont donc permis la mise en oeuvre des micropoutres selon deux principes de détections différents: l'un reposant sur la variation de masse du capteur à base de micropoutre lors de l'absorption de composé par une couche sensible; l'autre reposant sur la détection de changements de propriétés physiques du fluide environnant. / In order to optimize the use of microcantilever in the way of chemical sensing, microporous sensitive coatings have been tried to detect ethanol, toluene and humidity. The use of microcantilever without sensitive coating have been performed and simple models has been made and permit to predict the response of microcantilever in different environments. These studies rely on the use of microcantilever within two different detection mode: the detection of mass variation of the sensor because of the sorption of species in sensitive coating; and the detection of the change of physical properties of the fluid.

Détection

Capteurs chimiques

Micropoutres

Fréquence de résonance

Facteur de qualité

Zéolithes

Detection

Chemical sensors

Microcantilevers

Resonant frequency

Quality factor

Zeolites